source file of the GNU LilyPond music typesetter
- (c) 1997--1999 Han-Wen Nienhuys <hanwen@cs.uu.nl>
+ (c) 1997--2004 Han-Wen Nienhuys <hanwen@cs.uu.nl>
*/
+#include <math.h> // rint
+#include <stdio.h>
#include "gourlay-breaking.hh"
-#include "colhpos.hh"
-#include "spring-spacer.hh"
-#include "debug.hh"
+#include "column-x-positions.hh"
+#include "warn.hh"
+#include "main.hh"
#include "paper-column.hh"
#include "paper-score.hh"
#include "paper-def.hh"
-
-#include "killing-cons.tcc"
+#include "simple-spacer.hh"
+#include "system.hh"
/// How often to print operator pacification marks?
const int HAPPY_DOTS_I = 3;
considered: this path has infinite energy
*/
- int prev_break_i_;
- int line_i_;
- Real energy_f_;
+ int prev_break_;
+ /**
+ Which system number so far?
+ */
+ int line_;
+
+ Real demerits_;
Column_x_positions line_config_;
+
Break_node ()
{
- prev_break_i_ = -1;
- line_i_ = 0;
+ prev_break_ = -1;
+ line_ = 0;
+ demerits_ = 0;
+ }
+
+ void print () const
+ {
+ printf ("prev break %d, line %d, demerits %f\n",
+ prev_break_, line_, demerits_);
}
};
+void
+print_break_nodes (Array<Break_node> const & arr)
+{
+ for (int i =0; i < arr.size (); i++)
+ {
+ printf ( "node %d: ", i);
+ arr[i].print ();
+ }
+}
+
/**
This algorithms is adapted from the OSU Tech report on breaking lines.
+
+ this function is longish, but not very complicated.
*/
-
Array<Column_x_positions>
Gourlay_breaking::do_solve () const
{
Array<Break_node> optimal_paths;
- Line_of_cols all = pscore_l_->col_l_arr_ ;
+ Link_array<Grob> all =
+ pscore_->system_->columns ();
+
Array<int> breaks = find_break_indices ();
- optimal_paths.set_size (breaks.size ());
-
Break_node first_node ;
- first_node.prev_break_i_ = -1;
- first_node.line_config_.energy_f_ = 0;
- first_node.line_i_ = 0;
-
- optimal_paths[0] = first_node;
- int break_idx=1;
+ optimal_paths.push (first_node);
+ Real worst_force = 0.0;
- for (; break_idx< breaks.size (); break_idx++)
+ for (int break_idx=1; break_idx< breaks.size (); break_idx++)
{
- Array<int> candidates;
- Array<Column_x_positions> candidate_lines;
- Cons_list<Line_spacer> spacer_p_list;
-
/*
start with a short line, add measures. At some point
the line becomes infeasible. Then we don't try to add more
*/
+ int minimal_start_idx = -1;
+ Column_x_positions minimal_sol;
+ Column_x_positions backup_sol;
+
+ Real minimal_demerits = infinity_f;
+
+ bool ragged = to_boolean (pscore_->paper_->get_scmvar ("raggedright"));
+
for (int start_idx = break_idx; start_idx--;)
{
- if (break_idx - start_idx > max_measures_i_)
- break;
-
- if (optimal_paths[start_idx].prev_break_i_ < 0
- && optimal_paths[start_idx].line_config_.energy_f_)
-
- continue;
-
- Line_of_cols line = all.slice (breaks[start_idx], breaks[break_idx]+1);
+ Link_array<Grob> line = all.slice (breaks[start_idx], breaks[break_idx]+1);
- line[0] = dynamic_cast<Paper_column*>(line[0]->find_prebroken_piece (RIGHT));
- line.top () = dynamic_cast<Paper_column*>(line.top ()->find_prebroken_piece (LEFT));
+ line[0] = dynamic_cast<Item*> (line[0]) ->find_prebroken_piece (RIGHT);
+ line.top () = dynamic_cast<Item*> (line.top ())->find_prebroken_piece (LEFT);
- if (!feasible (line))
- break;
-
- Column_x_positions approx;
- approx.cols = line;
-
- approx.spacer_l_ = generate_spacing_problem (line,
- pscore_l_->paper_l_->line_dimensions_int (optimal_paths[start_idx].line_i_));
- spacer_p_list.append (new Killing_cons<Line_spacer> (approx.spacer_l_,0));
+ Column_x_positions cp;
+ cp.cols_ = line;
- ( (Break_algorithm*)this)->approx_stats_.add (approx.cols);
- approx.approximate_solve_line ();
-
- if (approx.energy_f_ > energy_bound_f_)
- {
- continue;
- }
+ Interval line_dims
+ = pscore_->paper_->line_dimensions_int (optimal_paths[start_idx].line_);
+ Simple_spacer * sp = generate_spacing_problem (line, line_dims);
+ sp->solve (&cp, ragged);
+ delete sp;
-
- // this is a likely candidate. Store it.
- candidate_lines.push (approx);
- candidates.push (start_idx);
- }
+ if (fabs (cp.force_) > worst_force)
+ worst_force = fabs (cp.force_);
-
- int minimal_j = -1;
- Real minimal_energy = infinity_f;
- for (int j=0; j < candidates.size (); j++)
- {
- int start = candidates[j];
- if (optimal_paths[start].line_config_.energy_f_
- + candidate_lines[j].energy_f_ > minimal_energy)
-
- continue;
+ /*
+ We remember this solution as a "should always work
+ solution", in case everything fucks up. */
+ if (start_idx == break_idx - 1)
+ backup_sol = cp;
+
+ Real this_demerits;
- if (!candidate_lines[j].satisfies_constraints_b_)
- {
- candidate_lines[j].solve_line ();
- ( (Break_algorithm*)this)->exact_stats_.add (candidate_lines[j].cols);
- }
-
- Real this_energy
- = optimal_paths[start].line_config_.energy_f_
- + candidate_lines[j].energy_f_ ;
-
- if (this_energy < minimal_energy)
+ if (optimal_paths[start_idx].demerits_ >= infinity_f)
+ this_demerits = infinity_f;
+ else
+ this_demerits = combine_demerits (optimal_paths[start_idx].line_config_, cp)
+ + optimal_paths[start_idx].demerits_;
+
+ if (this_demerits < minimal_demerits)
{
- minimal_j = j;
- minimal_energy = this_energy;
+ minimal_start_idx = start_idx;
+ minimal_sol = cp;
+ minimal_demerits = this_demerits;
}
+
+ /*
+ we couldn't satisfy the constraints, this won't get better
+ if we add more columns, so we get on with the next one
+ */
+ if (!cp.satisfies_constraints_b_)
+ break ;
}
- if (minimal_j < 0)
+
+ Break_node bnod;
+ if (minimal_start_idx < 0)
{
- optimal_paths[break_idx].prev_break_i_ = -1;
- optimal_paths[break_idx].line_config_.energy_f_ = infinity_f;
+ bnod.demerits_ = infinity_f;
+ bnod.line_config_ = backup_sol;
+ bnod.prev_break_ = break_idx - 1;
}
else
{
- optimal_paths[break_idx].prev_break_i_ = candidates[minimal_j];
- optimal_paths[break_idx].line_config_ = candidate_lines[minimal_j];
- optimal_paths[break_idx].line_i_ =
- optimal_paths[optimal_paths[break_idx].prev_break_i_].line_i_ + 1;
+ bnod.prev_break_ = minimal_start_idx;
+ bnod.demerits_ = minimal_demerits;
+ bnod.line_config_ = minimal_sol;
}
-
+ bnod.line_ = optimal_paths[bnod.prev_break_].line_ + 1;
+ optimal_paths.push (bnod);
+
if (! (break_idx % HAPPY_DOTS_I))
- *mlog << "[" << break_idx << "]" << flush;
-
- spacer_p_list.junk ();
+ progress_indication (String ("[") + to_string (break_idx) + "]");
}
- if (break_idx % HAPPY_DOTS_I)
- *mlog << "[" << break_idx << "]" << flush;
+ /* do the last one */
+ if (breaks.size () % HAPPY_DOTS_I)
+ progress_indication (String ("[") + to_string (breaks.size()) + "]");
- Array<int> final_breaks;
+ progress_indication ("\n");
+ Array<int> final_breaks;
Array<Column_x_positions> lines;
/* skip 0-th element, since it is a "dummy" elt*/
for (int i = optimal_paths.size ()-1; i> 0;)
{
final_breaks.push (i);
- assert (i > optimal_paths[i].prev_break_i_);
-
- // there was no "feasible path"
- if (!optimal_paths[i].line_config_.config.size ()) {
- final_breaks.set_size (0);
- break;
- }
- i = optimal_paths[i].prev_break_i_;
+ int prev = optimal_paths[i].prev_break_;
+ assert (i > prev);
+ i = prev;
}
-
- for (int i= final_breaks.size (); i--;)
- lines.push (optimal_paths[final_breaks[i]].line_config_);
+ if (verbose_global_b)
+ {
+ progress_indication (_f ("Optimal demerits: %f",
+ optimal_paths.top ().demerits_) + "\n");
+ }
+
+ if (optimal_paths.top ().demerits_ >= infinity_f)
+ warning (_ ("No feasible line breaking found"));
+ for (int i= final_breaks.size (); i--;)
+ {
+ Column_x_positions cp (optimal_paths[final_breaks[i]].line_config_);
+
+ lines.push (cp);
+ if(!cp.satisfies_constraints_b_)
+ warning ("Could not find line breaking that satisfies constraints.");
+ }
return lines;
}
Gourlay_breaking::Gourlay_breaking ()
{
- get_line_spacer = Spring_spacer::constructor;
- energy_bound_f_ = infinity_f;
- max_measures_i_ = INT_MAX;
}
-void
-Gourlay_breaking::do_set_pscore ()
+
+
+/*
+ TODO: uniformity parameter to control rel. importance of spacing differences.
+
+ TODO:
+
+ mixing break penalties and constraint-failing solutions is confusing.
+ */
+Real
+Gourlay_breaking::combine_demerits (Column_x_positions const &prev,
+ Column_x_positions const &this_one) const
{
- energy_bound_f_ = pscore_l_->paper_l_->get_var ("gourlay_energybound");
- max_measures_i_ =int (rint (pscore_l_->paper_l_->get_var ("gourlay_maxmeasures")));
+ Real break_penalties = 0.0;
+ Grob * pc = this_one.cols_.top ();
+ if (pc->original_)
+ {
+ SCM pen = pc->get_grob_property ("penalty");
+ if (gh_number_p (pen) && fabs (gh_scm2double (pen)) < 10000)
+ {
+ break_penalties += gh_scm2double (pen);
+ }
+ }
+
+ /*
+ Q: do we want globally non-cramped lines, or locally equally
+ cramped lines?
+
+ There used to be an example file input/test/uniform-breaking to
+ demonstrate problems with this approach. When music is gradually
+ becoming denser, the uniformity requirement makes lines go from
+ cramped to even more cramped (because going from cramped
+ 3meas/line to relatively loose 2meas/line is such a big step.
+
+ */
+
+ Real demerit = abs (this_one.force_) + abs (prev.force_ - this_one.force_)
+ + break_penalties;
+
+ if (!this_one.satisfies_constraints_b_)
+ {
+ /*
+ If it doesn't satisfy constraints, we make this one
+ really unattractive.
+
+ add 20000 to the demerits, so that a break penalty
+ of -10000 won't change the result */
+ demerit = (demerit + 20000) >? 2000;
+
+ demerit *= 10;
+ }
+
+ return demerit;
}